1. Field of the Invention
The present invention relates to a photomultiplier tube for detecting incident light from outside,
2. Related Background Art
Conventionally, compact photomultiplier tubes by using of fine processing technology have been developed. For example, a flat surface-type photomultiplier tube which is arranged with a photocathode, dynodes and an anode on a translucent insulating substrate is known (refer to Patent Document 1 given below). The above-described structure makes it possible to detect weak light at a high degree of reliability and also to downsize a device.
However, in the above-described conventional photomultiplier tubes, there is a tendency that multiplied electrons are easily made incident on the surface of an insulating substrate installed between each adjacent stage of the dynodes. Therefore, it is possible that the insulating substrate is electrically charged that results in a decreased withstand voltage.
Therefore, the present invention has been made in view of the above problem, and an object of which is to provide a photomultiplier tube capable of preventing electrons from being made incident onto an insulation part between dynodes to improve a withstand voltage.
In order to solve the above problem, the photomultiplier tube of the present invention is a photomultiplier tube which is provided with a casing having a substrate on which a flat surface made with an insulating material is formed, an electron multiplying part having a 1st stage to an Nth stage (N denotes an integer of 2 or more) which are arrayed so as to be spaced away sequentially from a first end side to a second end side on the flat surface of the substrate, a photocathode which is installed on the first end side so as to be spaced away from the electron multiplying part, converting incident light from outside to photoelectrons to emit the photoelectrons, an anode part which is installed on the second end side so as to be spaced away from the electron multiplying part, taking out electrons multiplied by the electron multiplying part as a signal, in which a groove, the surface of which is made with an insulating material, is formed between two adjacent stages of the electron multiplying part on the flat surface of the substrate, and the electron multiplying part constituted with the 1st stage to the Nth stage is fixed on raised parts adjacent to the grooves on the substrate.
According to the above-described photomultiplier tube, incident light is made incident onto the photocathode and converted to photoelectrons, and the photoelectrons are made incident onto the electron multiplying part constituted with a plurality of stages on the substrate and multiplied accordingly, and the thus multiplied electrons are outputted as an electric signal from the anode part. In this instance, an insulative groove is formed on the surface of the substrate between adjacent stages of the electron multiplying part, thus making it possible to prevent electrons passing between adjacent stages of the electron multiplying part from being made incident onto the surface of the substrate. It is, thereby, possible to prevent a decrease in withstand voltage that results from electric charge on the surface of the substrate.
It is preferable that the groove is formed over a range held between the edge part of a K-1th stage electron multiplying part on the second end side and the edge part of a Kth stage (K denotes an integer of 2 or more but N or less) electron multiplying part on the first end side. In this instance, the orbit of electrons between adjacent stages of the electron multiplying part can be reliably separated from the surface of the substrate, thus making it possible to effectively prevent electrons from being made incident onto the surface of the substrate.
It is also preferable that the groove is formed so as to reach to the second end side more than the edge part of the Kth stage electron multiplying part on the first end side. According to the above-described constitution, electrons passing between adjacent stages of the electron multiplying part are made incident onto the second end side of the groove to a lesser extent, thus making it possible to reduce electrons of being incident onto the surface of the substrate.
Further, it is preferable that the groove is formed so as to reach to the first end side more than the edge part of the K-1th stage electron multiplying part on the second end side. In this instance, electrons passing through adjacent stages of the electron multiplying part are made incident onto the first end side of the groove to a lesser extent, thus making it possible to reduce electrons of being incident onto the surface of the substrate.
Still further, it is preferable that a groove which communicatively connects between adjacent grooves at the end parts of the raised parts is also formed on the flat surface of the substrate. Thereby, the electron multiplying part on the raised parts is separated from the substrate to further improve a withstand voltage.
Hereinafter, a detailed description will be given for preferred embodiments of the photomultiplier tube related to the present invention by referring to drawings. In addition, in describing the drawings, the same or corresponding parts will be given the same reference numerals to avoid cumulative description.
The photomultiplier tube 1 shown in
In addition, in the following description, the upstream side of an electron multiplying channel (the side of the photocathode) along a direction at which electrons are multiplied is described as “a first end side,” while the downstream side (the side of the anode part) is described as “a second end side.” Further, a detailed description will be given for individual constituents of the photomultiplier tube 1.
As shown in
The side-wall frame 3 is constituted with a rectangular flat-plate like silicon substrate 30 as a base material. A penetration part 301 enclosed with a frame-like side wall part 302 is formed from a main surface 30a of the silicon substrate 30 to a surface 30b opposing thereto. The penetration part 301 is provided with a rectangular opening and an outer periphery of which is formed so as to run along the outer periphery of the silicon substrate 30.
Inside the penetration part 301, the focusing electrodes 37, the electron multiplying part 31 and the anode part 32 are formed from the first end side to the second end side. These focusing electrodes 37, the electron multiplying part 31 and the anode part 32 are formed by processing the silicon substrate 30 according to reactive ion etching (RIE) or other processing methods, with silicon used as a main raw material. The focusing electrodes 37 are electrodes for guiding photoelectrons emitted from the photocathode 22 that is later described into the electron multiplying part 31 and installed between the photocathode 22 and the electron multiplying part 31. The electron multiplying part 31 includes N stages (N denotes an integer of two or more) of dynodes (electron multiplying parts) set different in potential from the photocathode 22 to the anode part 32 along a direction at which electrons are multiplied and provided with a plurality of electron multiplying channels at each stage. The anode part 32 is positioned so as to hold the electron multiplying part 31 together with the photocathode 22. The electron multiplying part 31 and the anode part 32 are individually connected to the lower frame 4 by anode bonding, diffusion joining or joining using a sealing material such as a low-melting-point metal (for example, indium), by which they are arranged on the lower frame 4 two-dimensionally (the details will be described later). In addition, inside the penetration part 301, columnar parts (not illustrated) which electrically connect the photocathode 22 with conductive terminals 201 for the photocathode 22 are also formed similarly. Further, the electron multiplying part 31 and the focusing electrodes 37 are also individually connected to the corresponding conductive terminals 201 and set in a predetermined potential via the conductive terminals 201. For example, where dynodes are made of ten stages, a voltage of 100 to 1000V is applied in incremental steps at every 100V intervals to the photocathode 22 at the dynodes, and a voltage of 1100V is applied to the photocathode 22 at the anode part 32.
The lower frame 4 includes a rectangular flat-plate like glass substrate 40 as a base material. The glass substrate 40 forms a main surface 40a (flat surface) with glass which is an insulating material. The photocathode 22, which is a transmission-type photocathode, is formed at a site opposing the penetration part 301 of the side-wall frame 3 on the main surface 40a (a site other than a region joining with the side wall part 302) and at the end part opposite to the anode part 32.
Further, in a range on the main surface 40a where the photocathode 22, the focusing electrodes 37, the electron multiplying part 31 and the anode part 32 are fixed, a plurality of linear grooves 44 are formed along a direction intersecting with a direction at which a plurality of stages of dynodes are arrayed (a direction at which electrons are multiplied and a direction indicated by the arrow B in
Then, the internal structure of the photomultiplier tube 1 will be described in more detail by referring to
As shown in
The photocathode 22 is installed so as to be spaced away from the 1st stage dynode 31a to the first end side on the main surface 40a behind the focusing electrode 37, and the photocathode 22 is formed on the main surface 40a of the glass substrate 40 as a transmission-type photocathode. When incident light transmitted from outside through the glass substrate 40, which is the lower frame 4, arrives at the photocathode 22, photoelectrons corresponding to the incident light are emitted and the photoelectrons are guided into the electron multiplying part 31 by the focusing electrodes 37.
The anode part 32 is installed so as to be spaced away from the 10th stage dynode 31j to the second end side on the main surface 40a, and the anode part 32 is an electrode for outputting electrons which are multiplied by the electron multiplying part 31 in a direction indicated by the arrow B as an electric signal.
Further, the 3rd stage dynode 31c is spaced away from the 2nd stage dynode 31b to the second end side and fixed on the main surface 40a, and a linear groove 44b is formed between these two stages of dynodes 31b, 31c on the main surface 40a along a direction which is the same as that of the groove 44a. In a similar manner, the 4th stage dynode 31d to the 10th stage dynode 31j are spaced away sequentially behind the plurality of grooves 44 and fixed on the main surface 40a.
Due to the presence of the grooves 44a, 44b, the 1st stage dynode 31a to the 3rd stage dynode 31c are joined on the raised parts 45a to 45c respectively adjacent to the grooves 44a, 44b and extending linearly along a direction at which the grooves 44a, 44b extend. In a similar manner, the 4th stage dynode 31d to the 10th stage dynode 31j are joined on the raised parts 45 adjacent to the plurality of grooves 44. Joining surfaces of the raised parts 45 with the dynodes are flat surfaces and can be joined stably with the bottoms of the dynodes which are flat surfaces.
In this instance, the groove 44a is formed so as to go beyond a range held between the edge part 33a of the main surface 40a of the 1st stage dynode 31a on the second end side and the edge part 34b of the main surface 40a of the 2nd stage dynode on the first end side. In other words, the groove 44a is formed so as to spread to the second end side of the main surface 40a more than the edge part 34b of the 2nd stage dynode 31b and also formed so as to spread to the first end side of the main surface 40a more than the edge part 33a of the 1st stage dynode 31a, with the bottom formed in a flat surface shape. Further, the groove 44b is also formed so as to go beyond a range held between the edge part 33b of the main surface 40a of the 2nd stage dynode 31b on the second end side and the edge part 34c of the main surface 40a of the 3rd stage dynode 31c on the first end side. In a similar manner, all the grooves 44 held between the dynodes 31c to 31j are formed so as to go beyond a range held between two edge parts of dynodes 31c to 31j.
Since the grooves are structured as described above, the width L1 of a joining surface of the dynodes 31a to 31j along a direction at which each of them is arrayed on the main surface 40a (a direction along the arrow B in
According to the so-far described photomultiplier tube 1, incident light is made incident onto the photocathode 22 and thereby converted to photoelectrons. Then, the photoelectrons are made incident onto the electron multiplying part 31 having a plurality of stages on the glass substrate 40 and multiplied accordingly and the thus multiplied electrons are outputted as an electric signal from the anode part 32. In this instance, the insulating groove 44 is formed between adjacent stages of the electron multiplying part 31 on the main surface 40a of the glass substrate 40. Therefore, the glass substrate 40 is kept away from secondary electron surfaces of the dynodes, thus making it possible to prevent electrons passing between the dynodes of the electron multiplying part 31 from being made incident onto the main surface 40a. For example, where the dynodes 31a, 31b, 31c are joined on the glass substrate 40 having a flat surface (
Further, the photomultiplier tube 1 has an advantage of improving the productivity in processing the electron multiplying part 31.
As described above, after formation of the dynodes on the glass substrate 40, Al and Sb are deposited on them and thereafter they are subjected to alkali activation to form secondary electron surfaces. In this instance, the presence of the grooves 44 makes it possible to prevent adjacent dynodes from being electrically connected due to attachment of materials constituting secondary electron surfaces such as Al and Sb (conductive materials) on the glass substrate 40. On the other hand, where there are no grooves 44, in order to prevent a decrease of the withstand voltage between individual stages of dynodes due to attachment of conductive materials, care must be taken not to attach conductive materials between these stages of dynodes by using a mask such as SUS. Therefore, the photomultiplier tube 1 of the present embodiment eliminates such a necessity that uses the mask, thereby improving the production efficiency to a great extent.
Further, the grooves 44 can be provided between the photocathode 22 and the focusing electrode 37 and between the anode part 32 and the side wall part 302, thus making it possible to improve a withstand voltage between individual structures. Still further, the groove 46 for allowing the end part of each groove 44 to communicatively connect is provided, by which each of the raised parts 45 is completely spaced away by the groove 46 to improve the withstand voltage between individual structures. In addition, on development of stray electrons which are deviated from an electron multiplying channel, it is possible to prevent the electrons from being made incident onto the substrate 40 and also suppress external influences via the side wall part 302. The necessity for using a mask such as SUS is also eliminated, thereby preventing conductive materials from attachment between individual structures at the time of production.
The present invention shall not be limited to the above-described embodiments. For example, a range of the groove 44a formed on the glass substrate 40 may be such that is held between the edge part 33a of the 1st stage dynode 31a and the edge part 34b of the 2nd stage dynode 31b.
As shown in
In the present embodiment, the photocathode 22 is a transmission-type photocathode but may include a reflection-type photocathode. Further, the anode 32 may be arranged between the dynode 31i and the dynode 31j.
Number | Date | Country | Kind |
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P2009-042391 | Feb 2009 | JP | national |
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20100213838 A1 | Aug 2010 | US |